1. Chapter 5: Constraint Satisfaction ICS 171 Fall 2006

2. Sudoku Each row, column and major block must be alldifferent “Well posed” if it has unique solution: 27 constraints 2 3 4 6 2 Constraint propagation Variables: 81 slots Domains = {1,2,3,4,5,6,7,8,9} Constraints: 27 not-equal

3. Sudoku Each row, column and major block must be alldifferent “Well posed” if it has unique solution

4. Outline Constraint Satisfaction Problems (CSP) Backtracking search for CSPs Problem structure and problem decomposition Local search for CSPs

5. Constraint satisfaction problems (CSPs) Standard search problem: –state is a "black box“ – any data structure that supports successor function, heuristic function, and goal test CSP: –state is defined by variables X i with values from domain D i –goal test is a set of constraints specifying allowable combinations of values for subsets of variables Simple example of a formal representation language Allows useful general-purpose algorithms with more power than standard search algorithms

6. Example: Map-Coloring Variables WA, NT, Q, NSW, V, SA, T Domains D i = {red,green,blue} Constraints: adjacent regions must have different colors e.g., WA ≠ NT, or (WA,NT) in {(red,green),(red,blue),(green,red), (green,blue),(blue,red),(blue,green)}

7. Example: Map-Coloring Solutions are complete and consistent assignments, e.g., WA = red, NT = green,Q = red,NSW = green,V = red,SA = blue,T = green

8. Constraint graph Binary CSP: each constraint relates two variables Constraint graph: nodes are variables, arcs are constraints

9. Varieties of CSPs Discrete variables –finite domains: n variables, domain size d  O(d n ) complete assignments e.g., Boolean CSPs, incl.~Boolean satisfiability (NP-complete) –infinite domains: integers, strings, etc. e.g., job scheduling, variables are start/end days for each job need a constraint language, e.g., StartJob 1 + 5 ≤ StartJob 3 Continuous variables –e.g., start/end times for Hubble Space Telescope observations –linear constraints solvable in polynomial time by linear programming

10. Varieties of constraints Unary constraints involve a single variable, –e.g., SA ≠ green Binary constraints involve pairs of variables, –e.g., SA ≠ WA Higher-order constraints involve 3 or more variables, –e.g., cryptarithmetic column constraints

11. Example: Cryptarithmetic Variables: F T U W R O X 1 X 2 X 3 Domains: {0,1,2,3,4,5,6,7,8,9} Constraints: Alldiff (F,T,U,W,R,O) –O + O = R + 10 · X 1 –X 1 + W + W = U + 10 · X 2 –X 2 + T + T = O + 10 · X 3 –X 3 = F, T ≠ 0, F ≠ 0

12. Real-world CSPs Assignment problems –e.g., who teaches what class Timetabling problems –e.g., which class is offered when and where? Transportation scheduling Factory scheduling Notice that many real-world problems involve real-valued variables

13. Standard search formulation (incremental) Let's start with the straightforward approach, then fix it States are defined by the values assigned so far Initial state: the empty assignment { } Successor function: assign a value to an unassigned variable that does not conflict with current assignment  fail if no legal assignments Goal test: the current assignment is complete 1.This is the same for all CSPs 2.Every solution appears at depth n with n variables  use depth-first search 3.Path is irrelevant, so can also use complete-state formulation 4.b = (n - l )d at depth l, hence n! · d n leaves

14. Backtracking search Variable assignments are commutative, i.e., [ WA = red then NT = green ] same as [ NT = green then WA = red ] Only need to consider assignments to a single variable at each node  b = d and there are $d^n$ leaves Depth-first search for CSPs with single-variable assignments is called backtracking search Backtracking search is the basic uninformed algorithm for CSPs Can solve n-queens for n ≈ 25

15. Backtracking search

16. Backtracking example

20. Improving backtracking efficiency General-purpose methods can give huge gains in speed: –Which variable should be assigned next? –In what order should its values be tried? –Can we detect inevitable failure early?

21. The search space depends on the variable orderings

22. Search space and the effect of ordering

23. Most constrained variable Most constrained variable: choose the variable with the fewest legal values a.k.a. minimum remaining values (MRV) heuristic

24. Most constraining variable Tie-breaker among most constrained variables Most constraining variable: –choose the variable with the most constraints on remaining variables

25. Least constraining value Given a variable, choose the least constraining value: –the one that rules out the fewest values in the remaining variables Combining these heuristics makes 1000 queens feasible

26. Forward checking Idea: –Keep track of remaining legal values for unassigned variables –Terminate search when any variable has no legal values

27. Forward checking Idea: –Keep track of remaining legal values for unassigned variables –Terminate search when any variable has no legal values

28. Forward checking Idea: –Keep track of remaining legal values for unassigned variables –Terminate search when any variable has no legal values

29. Forward checking Idea: –Keep track of remaining legal values for unassigned variables –Terminate search when any variable has no legal values

30. Constraint propagation Forward checking propagates information from assigned to unassigned variables, but doesn't provide early detection for all failures: NT and SA cannot both be blue! Constraint propagation repeatedly enforces constraints locally

31. Arc consistency Simplest form of propagation makes each arc consistent X  Y is consistent iff for every value x of X there is some allowed y

32. Arc consistency Simplest form of propagation makes each arc consistent X  Y is consistent iff for every value x of X there is some allowed y

33. Arc consistency Simplest form of propagation makes each arc consistent X  Y is consistent iff for every value x of X there is some allowed y If X loses a value, neighbors of X need to be rechecked

34. Arc consistency Simplest form of propagation makes each arc consistent X  Y is consistent iff for every value x of X there is some allowed y If X loses a value, neighbors of X need to be rechecked Arc consistency detects failure earlier than forward checking Can be run as a preprocessor or after each assignment

35. Arc consistency algorithm AC-3 Time complexity: O(n 2 d 3 )

38. Arc-consistency 32,1, 32,1,32,1, 1  X, Y, Z, T  3 X  Y Y = Z T  Z X  T XY TZ 32,1,  =  

39. 1  X, Y, Z, T  3 X  Y Y = Z T  Z X  T XY TZ  =   13 23 Incorporated into backtracking search Arc-consistency

40. Arc-consistency algorithm domain of x domain of y Arc is arc-consistent if for any value of there exist a matching value of Algorithm Revise makes an arc consistent Begin 1. For each a in D i if there is no value b in D j that matches a then delete a from the D j. End. Revise is, k is the number of value in each domain.

41. Example applying AC-3

42. Sudoku Each row, column and major block must be alldifferent “Well posed” if it has unique solution

43. Sudoku Each row, column and major block must be alldifferent “Well posed” if it has unique solution

44. Sudoku Each row, column and major block must be alldifferent “Well posed” if it has unique solution: 27 constraints 2 3 4 6 2 Constraint propagation Variables: 81 slots Domains = {1,2,3,4,5,6,7,8,9} Constraints: 27 not-equal

45. Sudoku Each row, column and major block must be alldifferent “Well posed” if it has unique solution

51. Local search for CSPs Hill-climbing, simulated annealing typically work with "complete" states, i.e., all variables assigned To apply to CSPs: –allow states with unsatisfied constraints –operators reassign variable values Variable selection: randomly select any conflicted variable Value selection by min-conflicts heuristic: –choose value that violates the fewest constraints –i.e., hill-climb with h(n) = total number of violated constraints

52. Example: 4-Queens States: 4 queens in 4 columns (4 4 = 256 states) Actions: move queen in column Goal test: no attacks Evaluation: h(n) = number of attacks Given random initial state, can solve n-queens in almost constant time for arbitrary n with high probability (e.g., n = 10,000,000)

54. Summary CSPs are a special kind of problem: –states defined by values of a fixed set of variables –goal test defined by constraints on variable values Backtracking = depth-first search with one variable assigned per node Variable ordering and value selection heuristics help significantly Forward checking prevents assignments that guarantee later failure Constraint propagation (e.g., arc consistency) does additional work to constrain values and detect inconsistencies The CSP representation allows analysis of problem structure Tree-structured CSPs can be solved in linear time Iterative min-conflicts is usually effective in practice